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1	Determinação estrutural e estudo da estereoespecificidade de compostos de paládio II / Structural determination and stereospecificity studies of the palladium II compounds Oliveira, Milene Aparecida Rodrigues de 27 July 2010 (has links) Neste trabalho estão apresentadas as estruturas cristalinas e moleculares e o estudo da estereoespecificidade de compostos de paládio com geometria de coordenação quadrado planar. Estas estruturas foram determinadas com o objetivo de verificar a relação entre a geometria e sua potencialidade como um possível agente anti-cancerígeno.<br /> No estudo de correlação através de Quimiometria foi introduzida como parâmetros a distância do átomo de paládio ao plano, que avalia o quanto o átomo de paládio esta distante do plano formado pelos seus quatro ligantes, o ângulo de ligação, onde se observa a distorção dos ângulos entre os átomos coordenados ao paládio e a superfície de van der Waals calculada para a molécula.<br /> O estudo da relação destes parâmetros mostrou que eles são suficientes para realizar a separação entre ativos e inativos, indicando para os inéditos, com estrutura estudada neste trabalho, a possível (ou não) atividade. / This work presents the crystal and molecular structures and the study of stereospecificity of palladium compounds with square planar coordination geometry. These structures were determined with the objective of verifying the relationship between the molecular geometry and its potential as a possible anti-tumor agent.<br /> In the correlation study by Chemometry, the parameters introduced were: the distance from the palladium atom to the plane, which assesses how much the palladium atom is far from the plane formed by its four ligands, the bond angle, that shows a noticeable distortion of the angles between the atoms coordinated to the palladium atom, and van der Waals surface calculated for the molecule.<br /> The relationship between these parameters showed that they are sufficient to accomplish the separation between active and inactive molecules, indicating for the novel, with structure studied in this work, the possible (or not) activity. Estereoespecificidade Paládio II Palladium II Raio-X Stereospecificity X-ray
2	Determinação estrutural e estudo da estereoespecificidade de compostos de paládio II / Structural determination and stereospecificity studies of the palladium II compounds Milene Aparecida Rodrigues de Oliveira 27 July 2010 (has links) Neste trabalho estão apresentadas as estruturas cristalinas e moleculares e o estudo da estereoespecificidade de compostos de paládio com geometria de coordenação quadrado planar. Estas estruturas foram determinadas com o objetivo de verificar a relação entre a geometria e sua potencialidade como um possível agente anti-cancerígeno.<br /> No estudo de correlação através de Quimiometria foi introduzida como parâmetros a distância do átomo de paládio ao plano, que avalia o quanto o átomo de paládio esta distante do plano formado pelos seus quatro ligantes, o ângulo de ligação, onde se observa a distorção dos ângulos entre os átomos coordenados ao paládio e a superfície de van der Waals calculada para a molécula.<br /> O estudo da relação destes parâmetros mostrou que eles são suficientes para realizar a separação entre ativos e inativos, indicando para os inéditos, com estrutura estudada neste trabalho, a possível (ou não) atividade. / This work presents the crystal and molecular structures and the study of stereospecificity of palladium compounds with square planar coordination geometry. These structures were determined with the objective of verifying the relationship between the molecular geometry and its potential as a possible anti-tumor agent.<br /> In the correlation study by Chemometry, the parameters introduced were: the distance from the palladium atom to the plane, which assesses how much the palladium atom is far from the plane formed by its four ligands, the bond angle, that shows a noticeable distortion of the angles between the atoms coordinated to the palladium atom, and van der Waals surface calculated for the molecule.<br /> The relationship between these parameters showed that they are sufficient to accomplish the separation between active and inactive molecules, indicating for the novel, with structure studied in this work, the possible (or not) activity. Estereoespecificidade Paládio II Raio-X Palladium II Stereospecificity X-ray
3	Molecular modelling - understanding and prediction of enzyme selectivity. Fransson, Linda January 2009 (has links) <p>Molecular modelling strategies for evaluation of enzyme selectivity wereinvestigated with a focus on principles of how molecular interactionscould be evaluated to provide information about selectivity. Althoughmolecular modelling provides tools for evaluation of geometrical andenergy features of molecular systems, no general strategies for evaluationof enzyme selectivity exist. Geometrical analyses can be based uponinspection and reasoning about molecular interactions, which provide aneasily accessible way to gain information, but suffer from the risk of biasput in by the modeller. They can also be based on geometrical features ofmolecular interactions such as bond lengths and hydrogen-bond formation.Energy analyses are appealing for their modeller independenceand for the possibility to predict not only stereopreference, but also itsmagnitude.In this thesis, four examples of enantio- or regioselective serinehydrolase-catalysed reaction systems are presented together with developedmodelling protocols for explanation, prediction or enhancement ofselectivity. Geometrical as well as energy-based methodology were used,and provided an understanding of the structural basis of enzymeselectivity. In total, the protocols were successful in making qualitative explanationsand predictions of stereoselectivity, although quantitative determinationswere not achieved.</p> Biochemistry Biokemi
4	Molecular modelling - understanding and prediction of enzyme selectivity. Fransson, Linda January 2009 (has links) Molecular modelling strategies for evaluation of enzyme selectivity wereinvestigated with a focus on principles of how molecular interactionscould be evaluated to provide information about selectivity. Althoughmolecular modelling provides tools for evaluation of geometrical andenergy features of molecular systems, no general strategies for evaluationof enzyme selectivity exist. Geometrical analyses can be based uponinspection and reasoning about molecular interactions, which provide aneasily accessible way to gain information, but suffer from the risk of biasput in by the modeller. They can also be based on geometrical features ofmolecular interactions such as bond lengths and hydrogen-bond formation.Energy analyses are appealing for their modeller independenceand for the possibility to predict not only stereopreference, but also itsmagnitude.In this thesis, four examples of enantio- or regioselective serinehydrolase-catalysed reaction systems are presented together with developedmodelling protocols for explanation, prediction or enhancement ofselectivity. Geometrical as well as energy-based methodology were used,and provided an understanding of the structural basis of enzymeselectivity. In total, the protocols were successful in making qualitative explanationsand predictions of stereoselectivity, although quantitative determinationswere not achieved. Biochemistry and Molecular Biology Biokemi och molekylärbiologi
5	Investigating the Mechanisms and Specificities of BphI-BphJ, an Aldolase-Dehydrogenase Complex From Burkholderia xenovorans LB400 Baker, Perrin 11 May 2012 (has links) Microbial degradation of aromatic hydrocarbons is imperative for maintaining the global carbon cycle and removing potentially toxic aromatic xenobiotics. This thesis focuses on the characterization of a pyruvate-specific class II aldolase (BphI) and acetaldehyde dehydrogenase (BphJ), the final two enzymes of the bph meta-cleavage pathway in Burkholderia xenovorans LB400. This pathway is responsible for the degradation of the industrial pollutant polychlorinated biphenyls (PCB) and therefore mechanistic characterization of these enzymes can be applied to improve pollutant degradation. BphI catalyzes the aldol cleavage of 4-hydroxy-2-oxoacids to pyruvate and an aldehyde while BphJ transforms aldehydes to acyl-CoA, using NAD+ and CoASH as cofactors. Size-exclusion chromatography was used to determine that the oligomeric unit of the BphI-BphJ complex is a heterotetramer. The aldolase BphI was shown to exhibit a compulsory order mechanism and utilize 4-hydroxy-2-oxoacids with an S configuration at C4. The generation of BphI active site variants allowed for the proposal of a catalytic mechanism and a greater understanding as to how stereospecificity occurs. Using steady-state kinetic assays, Arg-16 was demonstrated to be essential for catalysis. Molecular modeling of the substrate and pH dependency (wild-type pKa of ~7, lost in H20A and H20S variants) were used to identify His-20 as the catalytic base. Tyr-290 was originally proposed to be the catalytic acid. However, this was refuted as a Tyr-290 (Y290F) variant did not affect the catalytic efficiency of the enzyme. Instead, the variant was observed to exhibit a loss of stereochemical control. From the crystal structure of an orthologous aldolase-dehydrogenase complex, solvent isotope effect studies, and a proton inventory, a water molecule was implicated as the catalytic acid. Based on their position within the crystal structure, Leu-87 and Leu-89 were implicated in substrate specificity. Replacement of Leu-89 with alanine effectively increased the length of the active site, allowing for the accommodation of longer aldehyde substrates. In contrast, Leu-87 was responsible for hydrophobic stabilization of the C4-methyl of the substrate. Double variants L87N;Y290F and L87W;Y290F were constructed to enable the binding of 4(R)-hydroxy-2-oxoacids. Polarimetric analysis confirmed that the double variants were able to synthesize 4-hydroxy-2-oxoacids of up to 8 carbons in lengths, which were of the opposite stereoisomer to those produced by the wild-type enzyme. Cys-131 was identified as the catalytic thiol that forms an acyl-enzyme intermediate in the dehydrogenase, BphJ. This enzyme was shown to exhibit similar specificity constants for acetaldehyde and propionaldehyde and utilize aliphatic aldehydes from two to five carbons in length as substrates. The enzyme was able to use either NAD+ or NADP+ as the cofactor. Finally, we demonstrated that aldehydes produced in the aldolase reaction are not released into the bulk solvent but are channeled directly to the dehydrogenase, providing the first biochemical determination of substrate channeling in any aldolase-dehydrogenase complex. / Chapter 3 - Reprinted (adapted) with permission from Baker, P., Carere, J., and Seah, S. Y. (2011) Probing the Molecular Basis of Substrate Specificity, Stereospecificity, and Catalysis in the Class II Pyruvate Aldolase, BphI, Biochemistry 50: 3559-3569. Copyright (2011) American Chemical Society. Chapter 4 - Reprinted (adapted) with permission from Baker, P., and Seah, S. Y. (2012) Rational design of stereoselectivity in the class II pyruvate aldolase BphI, J Am Chem Soc 134: 507-513. Copyright (2012) American Chemical Society. Chapter 6 - Reprinted (adapted) with permission from Baker, P., Hillis, C., Carere, J., and Seah, S. Y. (2012) Protein-protein interactions and substrate channeling in orthologous and chimeric aldolase-dehydrogenase complexes, Biochemistry 51: 1942-1952. Copyright (2012) American Chemical Society. / National Science and Engineering Research Council of Canada (NSERC), Ontario Graduate Scholarship in Science and Technology substrate channeling aldolase pyruvate acetaldehyde dehydrogenase catalytic mechanism mechanism enzyme stereospecificity stereochemical control mutagenesis allostery structure function substrate specificity
6	Structure d'une tagatose-1,6-bisphosphate aldolase de classe I : étude d'une apparente perte de stéréospécificité LowKam, Clotilde 10 1900 (has links) La tagatose-1,6-biphosphate aldolase de Streptococcus pyogenes est une aldolase de classe I qui fait montre d'un remarquable manque de spécificité vis à vis de ses substrats. En effet, elle catalyse le clivage réversible du tagatose-1,6-biphosphate (TBP), mais également du fructose-1,6-biphosphate (FBP), du sorbose-1,6-biphosphate et du psicose-1,6-biphosphate, quatre stéréoisomères, en dihydroxyacétone phosphate (DHAP) et en glycéraldéhyde-3-phosphate (G3P). Afin de mettre à jour les caractéristiques du mécanisme enzymatique, une étude structurale de la TBP aldolase de S. pyogenes, un pathogène humain extrêmement versatile, a été entreprise. Elle a permis la résolution de la structure native et en complexe avec le DHAP, a respectivement 1.87 et 1.92 Å de résolution. Ces mêmes structures ont permis de se représenter plus clairement le site actif de l'enzyme en général, et les résidus catalytiques en particulier. Le trempage des cristaux de TBP aldolase dans une solution saturante de DHAP a en outre permis de piéger un authentique intermédiaire iminium, ainsi que sa géométrie particulière en atteste. Des expériences d'échange de proton, entreprises afin d'évaluer le stéréoisomérisme du transfert de proton catalytique, ont également permis de faire une intéressante découverte : la TBP aldolase ne peut déprotoner le coté pro-R du C3 du DHAP, mais peut le protonner. Ce résultat, ainsi que la comparaison de la structure du complexe TBP aldolase-DHAP avec la structure du complexe FBP aldolase de muscle de lapin- DHAP, pointe vers un isomérisme cis-trans autour du lien C2-C3 de la base de Schiff formée avec le DHAP. De plus, la résolution de ces deux structures a permis de mettre en évidence trois régions très mobiles de la protéine, ce qui pourrait être relié au rôle postulé de son isozyme chez S. pyogenes dans la régulation de l’expression génétique et de la virulence de la bactérie. La cristallographie par rayons X et la cinétique enzymatique ont ainsi permis d'avancer dans l'élucidation du mécanisme et des propriétés structurales de cette enzyme aux caractéristiques particulières. / Tagatose-1,6-biphosphate aldolase from Streptococcus pyogenes is a class I aldolase that shows a lack of stereospecificity that is rare in enzymes in general, and in aldolases in particular. This aldolase catalyzes the reversible cleavage of tagatose-1,6-biphosphate (TBP), fructose-1,6-biphosphate (FBP), sorbose-1,6-biphosphate and psicose-1,6-biphosphate, four stereoisomers, in dihydroxyacetone phosphate and glyceraldehyde-3-phosphate (DHAP). In order to understand its mechanism, a structural study of TBP aldolase from S. pyogenes, one of the most versatile and virulent human pathogen, was initiated and high resolution crystallographic structures of native and DHAP-liganded TBP aldolase were solved. These structures allowed us to gain informations regarding active site residues implicated in catalysis and that give rise to the apparent lack of specificity. Soaking of TBP aldolase crystals in saturating DHAP solution specifically trapped the iminium intermediate, as demonstrated by its geometry. Furthermore, proton transfer studies uncovered an interesting phenomenon: TBP aldolase from S. pyogenes is unable to detritiate pro-R labelled hydrogen position at C3 of DHAP, yet it is able to tritiate both the pro-R and the pro-S position. These results, taken together with the superposition of the DHAP-TBP aldolase with the DHAP-FBP aldolase from rabbit muscle, suggest a cis-trans isomerism about the Schiff base C2-C3 bond. The resolution of both the native and the liganded structure also proved useful in identifying three very mobile regions in the protein. This trend could be linked to the putative metabolic sensor and genetic expression regulator role of LacD.1 in S. pyogenes. X-rays crystallography and traditional enzymatic kinetics allowed us to gain insights into the catalytic mechanism and others structural properties of this important metabolic enzyme. enzymologie crystallographie aldolase classe I stéréospécificité isomérisme Streptococcus pyogenes enzymology crystallography class I aldolase stereospecificity isomerism Streptococcus pyogenes
7	Effect of the Mutation D344P on the Regio and/or Stereospecificity of Cp3-O-Gt Spaulding, Nathan, Shivakumar, Devaiah P., McIntosh, Cecelia A. 08 August 2016 (has links) Plants produce a vast array of secondary metabolites. The phenolic compounds flavonoids are ubiquitous among plants and are known to aid in processes such as plant reproduction, UV defense, pigmentation and development. In relation to human health, flavonoids have also been found to possess anti-inflammatory, anti-cancer, and anti-oxidant properties. Flavonoids ability to participate in so many interactions is due in part to their subclass variation and further chemical modification. One such modification is glucosylation, where a glucose molecule is added to the flavonoid substrate, reactions catalyzed by glucosyltransferases. Citrus paradise contains a glucosyltransferase that is specific to the 3-O position of flavonols. To further understand the reactions it catalyzes, Cp3-O-GT structure was modelled against an anthocyanidin/flavonol 3 GT found in Vitis vinifera to identify candidate amino acids for mutations. Mutants were then created using site-directed mutagenesis, and one mutant, D344P, was constructed by an aspartate being replaced with a proline based off of the sequence comparison of the original enzymes. Biochemically characterizing the mutant D344P protein will determine whether the mutation has an effect on the regio and/or steriospecificity of Cp3-OGT. An initial screening assay has been performed using radioactive UDP-glucose as a sugar donor. Early results indicated that the mutant D344P has particular affinity for flavonols and for diosmetin, a flavone. Kinetic assays are being performed to confirm these results. Studies of time course, enzyme concentration, HPLC product analysis, pH optimum and reaction kinetics will be performed to further complete D344P protein characterization. effect mutation D344P regiospecificity stereospecificity Cp-3-O-GT flavonoids metabolites Biological Sciences School of Graduate Studies Biochemistry Molecular Biology Plant Biology
8	Rational redesign of Candida antarctica lipase B Magnusson, Anders January 2005 (has links) This thesis describes the use of rational redesign to modify the properties of the enzyme Candida antarctica lipase B. Through carefully selected single-point mutations, we were able to introduce substrate-assisted catalysis and to alter the reaction specificity. Other single-point mutations afforded variants with greatly changed substrate selectivity and enantioselectivity. Mutation of the catalytic serine changed the hydrolase activity into an aldolase activity. The mutation decreased the activation energy for aldol addition by 4 kJ×mol-1, while the activation energy increased so much for hydrolysis that no hydrolysis activity could be detected. This mutant can catalyze aldol additions that no natural aldolases can catalyze. Mutation of the threonine in the oxyanion hole proved the great importance of its hydroxyl group in the transition-state stabilization. The lost transition-state stabilization was partly replaced through substrate-assisted catalysis with substrates carrying a hydroxyl group. The poor selectivity of the wild-type lipase for ethyl 2-hydroxypropanoate (E=1.6) was greatly improved in the mutant (E=22), since only one enantiomer could perform substrate-assisted catalysis. The redesign of the size of the stereospecificity pocket was very successful. Mutation of the tryptophan at the bottom of this pocket removed steric interactions with secondary alcohols that have to position a substituent larger than an ethyl in this pocket. This mutation increased the activity 5 500 times towards 5-nonanol and 130 000 times towards (S)-1-phenylethanol. The acceptance of such large substituents (butyl and phenyl) in the redesigned stereospecificity pocket increases the utility of lipases in biocatalysis. The improved activity with (S)-1-phenylethanol strongly contributed to the 8 300 000 times change in enantioselectivity towards 1-phenylethanol; example of such a large change was not found in the literature. The S-selectivity of the mutant is unique for lipases. Its enantioselectivity increases strongly with temperature reaching a useful S-selectivity (E=44) at 69 °C. Thermodynamics analysis of the enantioselectivity showed that the mutation in the stereospecificity pocket mainly changed the entropic term, while the enthalpic term was only slightly affected. This pinpoints the importance of entropy in enzyme catalysis and entropy should not be neglected in rational redesign. Biochemistry Candida antarctica lipase B rational redesign secondary alcohols substrate-assisted catalysis S-selective entropy aldolase stereospecificity pocket oxyanion hole. Biokemi Biochemistry Biokemi
9	Structure d'une tagatose-1,6-bisphosphate aldolase de classe I : étude d'une apparente perte de stéréospécificité LowKam, Clotilde 10 1900 (has links) La tagatose-1,6-biphosphate aldolase de Streptococcus pyogenes est une aldolase de classe I qui fait montre d'un remarquable manque de spécificité vis à vis de ses substrats. En effet, elle catalyse le clivage réversible du tagatose-1,6-biphosphate (TBP), mais également du fructose-1,6-biphosphate (FBP), du sorbose-1,6-biphosphate et du psicose-1,6-biphosphate, quatre stéréoisomères, en dihydroxyacétone phosphate (DHAP) et en glycéraldéhyde-3-phosphate (G3P). Afin de mettre à jour les caractéristiques du mécanisme enzymatique, une étude structurale de la TBP aldolase de S. pyogenes, un pathogène humain extrêmement versatile, a été entreprise. Elle a permis la résolution de la structure native et en complexe avec le DHAP, a respectivement 1.87 et 1.92 Å de résolution. Ces mêmes structures ont permis de se représenter plus clairement le site actif de l'enzyme en général, et les résidus catalytiques en particulier. Le trempage des cristaux de TBP aldolase dans une solution saturante de DHAP a en outre permis de piéger un authentique intermédiaire iminium, ainsi que sa géométrie particulière en atteste. Des expériences d'échange de proton, entreprises afin d'évaluer le stéréoisomérisme du transfert de proton catalytique, ont également permis de faire une intéressante découverte : la TBP aldolase ne peut déprotoner le coté pro-R du C3 du DHAP, mais peut le protonner. Ce résultat, ainsi que la comparaison de la structure du complexe TBP aldolase-DHAP avec la structure du complexe FBP aldolase de muscle de lapin- DHAP, pointe vers un isomérisme cis-trans autour du lien C2-C3 de la base de Schiff formée avec le DHAP. De plus, la résolution de ces deux structures a permis de mettre en évidence trois régions très mobiles de la protéine, ce qui pourrait être relié au rôle postulé de son isozyme chez S. pyogenes dans la régulation de l’expression génétique et de la virulence de la bactérie. La cristallographie par rayons X et la cinétique enzymatique ont ainsi permis d'avancer dans l'élucidation du mécanisme et des propriétés structurales de cette enzyme aux caractéristiques particulières. / Tagatose-1,6-biphosphate aldolase from Streptococcus pyogenes is a class I aldolase that shows a lack of stereospecificity that is rare in enzymes in general, and in aldolases in particular. This aldolase catalyzes the reversible cleavage of tagatose-1,6-biphosphate (TBP), fructose-1,6-biphosphate (FBP), sorbose-1,6-biphosphate and psicose-1,6-biphosphate, four stereoisomers, in dihydroxyacetone phosphate and glyceraldehyde-3-phosphate (DHAP). In order to understand its mechanism, a structural study of TBP aldolase from S. pyogenes, one of the most versatile and virulent human pathogen, was initiated and high resolution crystallographic structures of native and DHAP-liganded TBP aldolase were solved. These structures allowed us to gain informations regarding active site residues implicated in catalysis and that give rise to the apparent lack of specificity. Soaking of TBP aldolase crystals in saturating DHAP solution specifically trapped the iminium intermediate, as demonstrated by its geometry. Furthermore, proton transfer studies uncovered an interesting phenomenon: TBP aldolase from S. pyogenes is unable to detritiate pro-R labelled hydrogen position at C3 of DHAP, yet it is able to tritiate both the pro-R and the pro-S position. These results, taken together with the superposition of the DHAP-TBP aldolase with the DHAP-FBP aldolase from rabbit muscle, suggest a cis-trans isomerism about the Schiff base C2-C3 bond. The resolution of both the native and the liganded structure also proved useful in identifying three very mobile regions in the protein. This trend could be linked to the putative metabolic sensor and genetic expression regulator role of LacD.1 in S. pyogenes. X-rays crystallography and traditional enzymatic kinetics allowed us to gain insights into the catalytic mechanism and others structural properties of this important metabolic enzyme. enzymologie crystallographie aldolase classe I stéréospécificité isomérisme Streptococcus pyogenes enzymology crystallography class I aldolase stereospecificity isomerism Streptococcus pyogenes
10	Metagenombasierte Isolierung und biochemische Charakterisierung neuartiger stereospezifischer Lipasen für biokatalytische Anwendungen / Metagenome based isolation and biochemical characterization of novel stereospecific lipases for biocatalytical applications Elend, Christian 01 November 2006 (has links) No description available. 570 Biowissenschaften, Biologie Mathematics and Computer Science Metagenom Lipase Biokatalyse Kälteaktive Enzyme Stereospezifität Ibuprofen Menthylacetat DNA-Microarray metagenome biocatalysis cold-active enzymes stereospecificity ibuprofen menthyl acetate DNA-microarray 42.13 42.30 58.30 WUE000 WUO400 WUV000

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